CN1571819A - Cross-linkable materials based on organosilicon compounds - Google Patents

Cross-linkable materials based on organosilicon compounds Download PDF

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CN1571819A
CN1571819A CNA02820509XA CN02820509A CN1571819A CN 1571819 A CN1571819 A CN 1571819A CN A02820509X A CNA02820509X A CN A02820509XA CN 02820509 A CN02820509 A CN 02820509A CN 1571819 A CN1571819 A CN 1571819A
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compound
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tin
base
formula
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CN1253509C (en
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沃尔夫冈·齐凯
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Wacker Chemie AG
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    • CCHEMISTRY; METALLURGY
    • C08ORGANIC MACROMOLECULAR COMPOUNDS; THEIR PREPARATION OR CHEMICAL WORKING-UP; COMPOSITIONS BASED THEREON
    • C08LCOMPOSITIONS OF MACROMOLECULAR COMPOUNDS
    • C08L83/00Compositions of macromolecular compounds obtained by reactions forming in the main chain of the macromolecule a linkage containing silicon with or without sulfur, nitrogen, oxygen or carbon only; Compositions of derivatives of such polymers
    • C08L83/04Polysiloxanes
    • CCHEMISTRY; METALLURGY
    • C08ORGANIC MACROMOLECULAR COMPOUNDS; THEIR PREPARATION OR CHEMICAL WORKING-UP; COMPOSITIONS BASED THEREON
    • C08GMACROMOLECULAR COMPOUNDS OBTAINED OTHERWISE THAN BY REACTIONS ONLY INVOLVING UNSATURATED CARBON-TO-CARBON BONDS
    • C08G77/00Macromolecular compounds obtained by reactions forming a linkage containing silicon with or without sulfur, nitrogen, oxygen or carbon in the main chain of the macromolecule
    • C08G77/04Polysiloxanes
    • C08G77/14Polysiloxanes containing silicon bound to oxygen-containing groups
    • CCHEMISTRY; METALLURGY
    • C08ORGANIC MACROMOLECULAR COMPOUNDS; THEIR PREPARATION OR CHEMICAL WORKING-UP; COMPOSITIONS BASED THEREON
    • C08GMACROMOLECULAR COMPOUNDS OBTAINED OTHERWISE THAN BY REACTIONS ONLY INVOLVING UNSATURATED CARBON-TO-CARBON BONDS
    • C08G77/00Macromolecular compounds obtained by reactions forming a linkage containing silicon with or without sulfur, nitrogen, oxygen or carbon in the main chain of the macromolecule
    • C08G77/04Polysiloxanes
    • C08G77/14Polysiloxanes containing silicon bound to oxygen-containing groups
    • C08G77/18Polysiloxanes containing silicon bound to oxygen-containing groups to alkoxy or aryloxy groups
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10STECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10S528/00Synthetic resins or natural rubbers -- part of the class 520 series
    • Y10S528/901Room temperature curable silicon-containing polymer

Abstract

The invention relates to materials, which can be cross-linked at room temperature and are based on organosilicon compounds with at least two hydrolyzable groups. These materials are characterized in that they contain at least one organotin compound (C) serving as a catalyst, whereby the organotin compound (C) can be obtained by reacting phosphorous compounds (i) with C-P(=O) (OH) units and sulfur compounds (ii) with -SO3H- groups and tin compounds (iii) containing units of formula (III): Ra(XR')bSnX(4-a-b)/2, wherein: R can be identical or different and represents monovalent optionally substituted hydrocarbon radicals, which can be interrupted by oxygen atoms; X can be identical or different and represents O- or S-; R' can be identical or different and represents a hydrogen atom or monovalent optionally substituted hydrocarbon radicals that can be interrupted by oxygen atoms; a represents 0, 1, 2 or 3, and; b represents 0, 1, 2 or 3, with the provision that the sum a+b </= 4.

Description

Crosslinkable materials based on silicoorganic compound
Technical field
The present invention be more particularly directed to crosslinkable at room temperature and based on the material of silicoorganic compound, for example so-called RTV-1 material, and relate to the special tin compound that can be used as these material inner catalysts.
Background technology
Is known with dialkyl tin (IV) compound as the condensation catalyst in RTV-1 and the RTV-2 silicon rubber.Yet, in RTV-1 alkoxyl group material, the shortcoming of these tin compounds is: these tin compounds are also by the siloxane bond of the non-hope of alcohol radical catalysis dissociate (" poising action "), the end alkoxy group of formed polysiloxane chain no longer can be implemented crosslinked, so the full cross-linked of this material no longer may; What promptly the predetermined mode of usefulness made is not vulcanizate or insufficient stable vulcanizate.(storable time of RTV-1 material) is significantly lowered the storage life in poising action, but does not significantly lose its characteristic.
The method of selecting at present to increase the storage life is:
Replace tin catalyst with titanium catalyst.Its shortcoming is that material is yellow, and the result becomes non-transparent material and can not become transparent material.
Lower the usage quantity of tin catalyst.
Use more weak tin catalyst, for example: the tin chelating catalyst.Need to use excessive chelate compound such as acetylacetonate; Yet this acetylacetonate is the volatility height, toxicity is unsafe and be harmful to health.
Add pure remover, because the hyperergy of pure remover, itself and alcohol reaction.Yet this adds very expensive and can damage tackiness usually.
As described in EP-A 850254, use catalyzer with Sn-O-P key, these catalyzer are to be reacted and made by phosphate monoester and organo-tin compound.Yet, having been found that the acid number of used phosphorus compound is very high, its usage quantity must be at least and mole or excessive such as tin compound, thereby cause adhesion problems, and is more remarkable when especially the tackiness seam contacts with water.Moreover US-A 3,525,778 and US-A 3,655,705 in the compound with Sn-O-P key that is made by phosphodiester is disclosed.
With the sulfonic acid end-blocking and to be used for the dialkyl group diacyl tin catalyst of polyurethane(s) known, its activation is to implement via amine.Just in this respect, can be for example with reference to US-A 5 849 864 and WO 99/11369, Ashland Chemical Company.
RTV-2 solidifying agent (catalyzer-crosslinker composition) based on organotin is disclosed among the DE-A 195 27 101; and it also can contain organic acid as the reaction times conditioning agent, and the reaction times conditioning agent is used to improve the reactivity of claimed catalyzer-crosslinker composition.
Disclose especially in condensation-cross-linked polymer system, to use and contained Sn-O-SO 2The compound of R, for example, these compounds can make from alkyl-tin oxide and sulfonic acid.Thus, for example, can be with reference to US-A 3,095,434 and US-A 5,981,685.What be not disclosed in request for utilization patent in the RTV siloxanes system in these examples contains the unitary catalyzer of sulfonic acid tin.Particularly, openly do not have the alkoxyl group RTV-1 system of relevant storage life specific question and the necessity of auxiliary catalysis additive.EP-A 623 642 is open: make if contained polymkeric substance is anionoid polymerization effect by ring type structure, and for example use phosphoric acid with the alkaline polymerization catalyzer that neutralizes, and contain for example alkali metal phosphate in the material, then add acids (comprising sulfonic acid) to stablize RTV-1 acetoxyl group material.
In the RTV system of filling, use the reaction product of sulfonic acid and amine or basic filler open, so that filler disperses and make the elastomerics of low modulus easily.Thus, for example, can be with reference to US-A 5,073,586 and US-A 5,118,738.
Summary of the invention
The present invention relates to crosslinkable materials based on silicoorganic compound with at least two hydrolyzable bases, wherein contain at least a organo-tin compound (C) as catalyzer, this organo-tin compound (C) can by have C-P (=O) (OH) unitary phosphorus compound (i) with have-SO 3The sulphur compound of H base (ii) reaches and contains the unitary tin compound of following formula and (iii) react and make
R a(XR′) bSn X(4-a-b)/2????????????????(III),
In the formula,
R can be identical or different and be monovalent, optional be substituted can be by Sauerstoffatom alkyl at interval,
X can be identical or different and be-O-or-S-,
R ' can be identical or different and be hydrogen atom or monovalent, optional be substituted can be by oxygen alkyl at interval, or the optional silyl that is substituted,
A be 0,1,2 or 3 and
B is 0,1,2 or 3,
Condition be a+b and be less than or equal to 4.
The R base is preferably the alkyl with 1 to 18 carbon atom, especially preferably has alkyl, especially normal-butyl and the n-octyl of 1 to 12 carbon atom.
The example of R base is: alkyl, for example: methyl, ethyl, n-propyl, sec.-propyl, 1-normal-butyl, 2-normal-butyl, isobutyl-, the tertiary butyl, n-pentyl, isopentyl, neo-pentyl and tert-pentyl; Hexyl, for example: n-hexyl; Heptyl, for example: n-heptyl; Octyl group, for example: n-octyl and iso-octyl, as: 2,2, the 4-tri-methyl-amyl; Nonyl, for example: n-nonyl; Decyl, for example: positive decyl; Dodecyl, for example: dodecyl; Octadecyl, for example: the Octadecane base; Cycloalkyl, for example: cyclopentyl, cyclohexyl and suberyl and methylcyclohexyl; Thiazolinyl, for example: vinyl, 1-propenyl and 2-propenyl; Aryl, for example: phenyl, naphthyl, anthryl and phenanthryl: alkaryl, for example: adjacent, and p-methylphenyl; Xylyl and ethylbenzene base; And aralkyl, for example: phenmethyl and α-and β-styroyl.
The R base example that is substituted is: methoxy ethyl, ethoxyethyl group and ethoxy ethoxy ethyl.
X is preferably Sauerstoffatom.
R ' base is preferably hydrogen atom and optional by alkoxyl group and/or amino replace and alkyl that have 1 to 18 carbon atom, especially preferably has alkyl and aryl, especially methyl and the ethyl of 1 to 18 carbon atom.
The example of R ' base is example and methoxy ethyl, ethoxyethyl group, methoxyethoxyethyl, amino ethoxy ethyl and the aminopropyl of described R.
Can be in order to the tin compound example (iii) of the preparation used tin compound of the present invention (C): tetra-n-butyl dimethoxy tin oxygen alkane, tetra-n-butyl diethoxy tin oxygen alkane, the oxidation di-n-butyl tin, tetra-n-butyl dihydroxyl tin oxygen alkane, di-n-butyl dimethoxy tin oxygen alkane, four positive hot dihydroxyl tin oxygen alkane, di-n-octyl dimethoxy tin oxygen alkane, eight normal-butyl diethoxies, four tin oxygen alkane, preferred tetra-n-butyl dimethoxy tin oxygen alkane, tetra-n-butyl diethoxy tin oxygen alkane and di-n-butyl dimethoxy tin oxygen alkane, preferred especially tetra-n-butyl dimethoxy tin oxygen alkane and di-n-butyl dimethoxy tin oxygen alkane.
Can be in order to the phosphorus compound of the preferred following formula of the phosphorus compound (i) of the preparation used tin compound of the present invention (C):
O=PR 1 mY n(OH) 3-m-n?????????????????????????(I),
Wherein
R 1Can be identical or different, and be optional that be substituted, that have 1 to 30 carbon atom, can be by Sauerstoffatom alkyl at interval,
Y is OR 2,-NR 2 2Or hydrogen atom, wherein R 2Can be identical or different and the meaning and the described R of representative 1Identical, maybe can be the optional silyl that is substituted,
N be 0 or 1 and
M is 1 or 2, condition be m+n and be 1 or 2.
R 1And R 2The example of base is identical with described R base.
The R that is substituted 1And R 2Example be independently of one another: hydroxyalkyl, alkylhalide group and Qing Wanji and-(CH 2CH 2O) zR " base of structure, wherein R " is that methyl, ethyl or butyl and z are 1 to 18 integers.
The R1 base is preferably aryl, alkaryl or alkyl, is preferably aryl or alkyl especially, especially octyl group, phenmethyl or phenyl.
R 2Base is preferably aryl or alkyl, special preferred alkyl, especially methyl, ethyl or butyl.
The Y base is preferably alkoxyl group or aryloxy, preferred especially alkoxyl group, especially methoxyl group, oxyethyl group or butoxy.
M is preferably 1.
N is preferably 0.
The example of phosphorus compound (i) is: phenyl-phosphonic acid, benzene phosphonous acid, p-aminophenyl phosphonic acids, n-octyl phosphonic acids and 2-amino-8-phosphono are sad, wherein preferred phenyl-phosphonic acid and n-octyl phosphonic acids.
The sulphur compound that can be used for preparing the used tin compound of the present invention (C) the (ii) sulphur compound of preferred following formula is:
R 3-S(=O) 2OH?????????????????????????(II),
Wherein
R 3Can be identical or different and be via the amido of nitrogen bond or monovalent, optional that be substituted, can by-S (=O) 2-alkyl at interval.
Preferred R 3Base for optional by-SO 3H replace and have 1 to 40 carbon atom, can be by-S (O) 2-at interval alkyl especially preferably has the alkyl or aryl of 1 to 40 carbon atom, especially through alkyl aryl that replace, that have 7 to 40 carbon atoms.
R 3The example of base is that the example of described R reaches-NH 2,-C 6H 4-SO 3H reaches-C 4H 8-SO 3H.
Sulphur compound example (ii) is: Witco 1298 Soft Acid, tosic acid, Phenylsulfonic acid and 1,3-benzene disulfonic acid, wherein preferred Witco 1298 Soft Acid and tosic acid, preferred especially Witco 1298 Soft Acid.
Compound (i), (ii) reach (iii) and respectively make for commerical prod or the known method of available organic chemistry.
The used organo-tin compound of the present invention (C) can be stannane and oligomeric or high poly-tin compound, for example: tin oxygen alkane.
Catalyst system therefor of the present invention (C) is preferably stannane or straight chain type tin oxygen alkane.
The example of catalyst system therefor of the present invention (C) is: Oct 2Sn (OP (=O) Ph (OH)) (OSO 2-C 6H 4-CH 3), Oct 2Sn (O-P (=O) Oct (OEt))-O-SnOct 2(OSO 2-C 6H 4-C 12H 23), Bu 2Sn (O-P (=O) Oct (OH))-O-SnBu 2(OSO 2-C 6H 4-C 12H 23), Bu 2Sn[O-P (=O) Oct (O-Bu 2Sn (OEt))]-O-SnBu 2(OSO 2-C 6H 4-C 12H 23), Oct 2Sn (O-P (=O) Oct (OH))-O-SnOct 2(OSO 2-C 6H 4-C 12H 23), Oct 2Sn (O-P (=O) Oct (OEt))-(O-SnOct 2) 9(OSO 2-C 6H 4-C 12H 23), preferred Oct 2Sn (O-P (=O) Oct (OEt))-O-SnOct 2(OSO 2-C 6H 4-C 12H 23), Bu 2Sn[O-P (=O) Oct (O-Bu 2Sn (OEt))-O-SnBu 2(OSO 2-C 6H 4-C 12H 23), Bu 2Sn (O-P (=O) Oct (OH))-O-SnBu 2(OSO 2-C 6H 4-C 12H 23) and Oct 2Sn (O-P (=O) Oct (OH))-O-SnOct 2(OSO 2-C 6H 4-C 12H 23), preferred especially Oct 2Sn (O-P (=O) Oct (OH))-O-SnOct 2(OSO 2-C 6H 4-C 12H 23) and Bu 2Sn (O-P (=O) Oct (OH))-O-SnBu 2(OSO 2-C 6H 4-C 12H 23), wherein Et is an ethyl, Bu is that normal-butyl and Oct are n-octyls.
The invention still further relates to a kind of organo-tin compound, its can by have C-P (=O) (OH) unitary phosphorus compound (i) with have-SO 3The sulphur compound of H base (ii) reaches to contain to have the unitary tin compound of following formula and (iii) reacts and make:
R a(XR′) bS nX (4-a-b)/2????????????????????(III),
Wherein the definition of R, X, R ', a and b is same as described above, condition be a+b and be less than or equal to 4.
The known method of the available organic chemistry of organo-tin compound (C) of the present invention or that the present invention is used makes, for example: by making the corresponding organo-tin compound and the mixture reaction of sulfonic acid or sulfonic acid and phosphonic acids or phosphonate derivative.Just in this respect, for example: can be with reference to A.G Davies, Organotin Chemistry, VCH Verlagsgesellschaft, Weinheim, 1997, Section11.3 (Reactions with P-containing acids) and 11.4 (Reactions withP-containing acids).
The used organo-tin compound of the present invention or the present invention (C) is preferably 0 to 150 ℃ temperature, at environment atmospheric pressure, promptly under about 900 to 1,100 hundred pascals, makes compound (i), (ii) reaches (iii) that reaction prepares, 20 to 60 ℃ of preferred especially temperature.
According to the present invention, at compound (i), (ii) reach in (iii) the reaction, be benchmark with 1 mole of tin compound tin atom (iii), the usage quantity of phosphorus compound (i) is preferably 0.1 to 2.0 mole, preferred especially 0.2 to 1.0 mole.
According to the present invention, at compound (i), (ii) reach in (iii) the reaction, be benchmark with 1 mole of tin compound tin atom (iii), sulfonic acid usage quantity (ii) is preferably 0.05 to 1.5 mole, preferred especially 0.1 to 0.5 mole.
In preparation catalyst system therefor of the present invention (C), but also original position is with starting raw material (i), (ii) reach and (iii) be added directly in other crosslinkable materials components, and this kind situation will be included in the disclosed content, but not preferred.If catalyzer of the present invention (C) is in-situ preparing, preferred basic components only tin compound (iii), add behind the sulphur compound reaction in (ii) and phosphorus compound (i).
Except that organo-tin compound (C), preferably contain compound (D) based on the material of the present invention of silicoorganic compound.
Containing alkaline nitrogen compound (D) can be amine, nitrogen heterocyclic ring or amino functional silicoorganic compound, the preferred latter.
The example of amino functional silicoorganic compound (D) is: have the silane of basic nitrogen, have the organo-siloxane of basic nitrogen, for example: the compound of formula V, wherein at least one R 6The meaning of base is the alkyl that is replaced by amino.
Compound and partial hydrolysate thereof with preferred following formula of silicoorganic compound (D) of basic nitrogen:
(R 9O) 4-gSiR 10 g???????????????????????????(IV),
R wherein 9Can be identical or different and have one of above-mentioned R ' meaning,
R 10Can be identical or different and be monovalent, the optional alkyl that is substituted with basic nitrogen, and
G is 1,2,3 or 4,
Described partial hydrolysate can be part with first hydrolysate, be the partial hydrolysate of a kind of formula (IV) silicoorganic compound, and part cohydrolysis product, the i.e. partial hydrolysate of at least two kinds of formulas (IV) silicoorganic compound.
If the optional compound (D) that uses is the partial hydrolysate of formula (IV) silicoorganic compound in the material of the present invention, then preferred its has up to 6 Siliciumatoms.
R 9The example of base is identical with the example of above-mentioned R ' base.R 9Preferred hydrogen atom of base and alkyl, preferred especially hydrogen atom and have alkyl, especially hydrogen atom, methyl and the ethyl of 1 to 4 carbon atom.
R 10The example of base is: aminomethyl, 1-aminoethyl, 3-aminopropyl, 3-(2-aminoethyl) aminopropyl, aminoethyl aminoethyl aminopropyl and cyclohexyl aminopropyl.
R 10Base is preferably 3-aminopropyl, 3-(2-aminoethyl) aminopropyl, aminoethyl aminoethyl aminopropyl and cyclohexyl aminopropyl, preferred especially 3-aminopropyl and 3-(2-aminoethyl) aminopropyl.
The present invention is optional to be used and example with compound (D) of basic nitrogen atom is: the 3-aminopropyl trimethoxysilane, the 3-aminopropyl triethoxysilane, 3-(2-aminoethyl amino) propyl trimethoxy silicane, 3-(2-aminoethyl amino) propyl-triethoxysilicane, 3-(N, N-diethyl-2-aminoethyl amino) propyl trimethoxy silicane, 3-(N, N-diethyl-2-aminoethyl amino) propyl-triethoxysilicane, 3-(cyclohexyl amino) propyl trimethoxy silicane, 3-(cyclohexyl amino) propyl-triethoxysilicane, the partial hydrolysate of aminomethyl Trimethoxy silane and these alkoxy-functional silicoorganic compound.
The optional compound (D) that uses of the present invention is commerical prod or can be made by the known method of organic chemistry.
Except that organo-tin compound (C) and optional the having alkaline nitrogen compound (D) of using of the present invention as condensation catalyst, material of the present invention can contain all components that the crosslinkable organopolysiloxane material has used under the present preparation room temperature.The hydrolyzable group that used and relevant silicoorganic compound can have in crosslinking reaction can be any required base, for example: and acetoxyl group, oximate base and organic oxygen base, especially alkoxyl group, for example: oxyethyl group, alkoxyl group oxyethyl group and methoxyl group.Moreover silicoorganic compound can be siloxanes (≡ Si-O-Si ≡ structure) and silicon-carbon alkane (≡ Si-R -Si ≡ structure, wherein R is optional by heteroatoms replacement or two valency alkyl at interval) or its multipolymer.
Crosslinkable materials of the present invention preferably contains following component:
(A) have at least two organopolysiloxanes that are selected from the hydrolyzable base of acetoxyl group, oximate base and organic oxygen base, optional
(B) have at least three linking agents that are selected from the hydrolyzable base of acetoxyl group, oximate base and organic oxygen base, and/or its partial hydrolysate,
(C) can (ii) reach tin compound by phosphorus compound (i), sulphur compound and (iii) react the organo-tin compound that makes, and optional
(D) has alkaline nitrogen compound (D).
Used and the organopolysiloxane (A) that have at least two hydrolyzable bases of the present invention is preferably the organopolysiloxane of following formula:
(R 5O) 3-dR 6 dSiO-[R 6 2SiO] e-SiR 6 d(OR 5) 3-d??????(V),
Wherein
D is 0,1 or 2,
R 6It is SiC-bond alkyl identical or different, that have 1 to 18 carbon atom, these bases are optional to be replaced by halogen atom, ether, ester group, epoxy group(ing), sulfydryl, cyano group, amino or (gathering) glycol-based, the latter is made up of oxyethylene group and/or oxypropylene group unit, and
R 5Can be identical or different and the meaning of representative identical with described R ',
E is 10 to 10000 integer, and preferred 100 to 3000, preferred especially 400 to 2000 is better,
Condition is only to work as R 5When being hydrogen atom, d can be 2.
R 6The example of base is the example of above-mentioned R base.
R 6Base is preferably alkyl, especially preferably has alkyl, the especially methyl of 1 to 4 carbon atom.
R 5The example of base is identical with the example of above-mentioned R ' base.
R 5Base is preferably hydrogen atom and alkyl, preferred especially hydrogen atom and have alkyl, especially hydrogen atom, methyl and the ethyl of 1 to 4 carbon atom.
Select the mean values of e in the formula V, the viscosity that makes the organopolysiloxane of formula V measure under 25 ℃ of temperature is 1000 to 2500000 milli pascal seconds, preferred especially 4000 to 800000 milli pascal seconds.
Though do not show in the formula V and can not confirm from the title of diorganopolysiloxanecompositions, can be up to the two organo-siloxane unit of 10 moles of % by other siloxane units replacements, for example: R 6 3SiO 1/2, R 6SiO 3/2And SiO 4/2Unit, wherein R 6The meaning of representative is same as described above.
The example that has the organopolysiloxane (A) of at least two organic oxygen bases in the material of the present invention on used and each end group is:
(MeO) 2MeSiO[SiMe 2O] 200-2000SiMe(OMe) 2
(EtO) 2MeSiO[SiMe 2O] 200-2000SiMe(OEt) 2
(MeO) 2ViSiO[SiMe 2O] 200-2000SiVi (OMe) 2, and
(EtO) 2ViSiO[SiMe 2O] 200-2000SiVi(OEt) 2
(MeO) 2(H 2N-CH 2CH 2CH 2)SiO[SiMe 2O] 200-2000Si(CH 2CH 2CH 2-NH 2)(OMe) 2
Wherein Me is a methyl, and Et is that ethyl and Vi are vinyl.
Used and silicoorganic compound (A) that have at least two hydrolyzable bases are that known method makes in commerical prod or the available silicon chemistry in the material of the present invention, and for example: by making α, the alpha, omega-dihydroxy organopolysiloxane reacts with corresponding organic radical TMOS.
The optional linking agent (B) that uses can be known at present and have any required linking agent of at least three hydrolyzable bases in the material of the present invention, for example: silane or siloxanes with at least three organic oxygen bases.
The silicoorganic compound and the partial hydrolysate thereof of the preferred following formula of the optional linking agent (B) that uses in the material of the present invention:
(R 7O) 4-fSiR 8 f?????????????????????????????????(VI),
R wherein 7Can be identical or different and have a kind of meaning of above-mentioned R ',
R 8Meaning with above-mentioned R reaches
F is 0 or 1.
Described partial hydrolysate can be part with first hydrolysate, be the partial hydrolysate of a kind of formula (VI) silicoorganic compound, and part cohydrolysis product, the i.e. partial hydrolysate of at least two kinds of different formulas (VI) silicoorganic compound.
If the optional linking agent (B) that uses is the partial hydrolysate of formula (VI) silicoorganic compound in the material of the present invention, then preferred its has up to 6 Siliciumatoms.
R 7The example of base is the example of above-mentioned R ' base.R 7Base is preferably hydrogen atom and alkyl, preferred especially hydrogen atom and have alkyl, especially hydrogen atom, methyl and the ethyl of 1 to 4 carbon atom.
R 8The example of base is the example of above-mentioned R base, preferably has the alkyl of 1 to 12 carbon atom, special preferable methyl and vinyl.
The optional linking agent (B) that uses especially preferably in the material of the present invention: tetramethoxy-silicane, tetraethoxysilane, tetrapropoxysilane, four butoxy silanes, methyltrimethoxy silane, Union carbide A-162, vinyltrimethoxy silane, vinyltriethoxysilane, phenyltrimethoxysila,e, phenyl triethoxysilane, 3-cyanogen propyl trimethoxy silicane, 3-cyanogen propyl-triethoxysilicane, 3-(glycidyl oxygen base) propyl-triethoxysilicane, 1, two (Trimethoxy silane base) ethane of 2-, 1, the partial hydrolysate of two (triethoxysilicane alkyl) ethane of 2-and these alkoxy-functional silicoorganic compound, for example: six oxyethyl group sily oxide.
In the material of the present invention the optional linking agent (B) that uses be commerical prod or also the known method of available silicon chemistry make.
If contain linking agent (B) in the material of the present invention, be benchmark always with 100 weight part organopolysiloxanes (A), its content is preferably 0.01 to 20 weight part, preferred especially 0.5 to 10 weight part, especially preferred 1.0 to 5.0 weight parts.Especially, if (for example) uses the compound with at least three hydrolyzable groups as component (D), also can save and add linking agent (B) or decrement.
Be benchmark with 100 weight part organopolysiloxanes (A) always, material of the present invention contains preferred 0.001 to the 5 weight % of amount of catalyzer (C), preferred especially 0.05 to 3 weight %, especially 0.1 to 1 weight %.
Material of the present invention preferably contains component (D).
If material of the present invention contains component (D), be benchmark always with 100 weight part organopolysiloxanes (A), its content is preferably 0.001 to 6 weight %, preferred especially 0.5 to 4 weight %, especially 1 to 3 weight %.
Except that described component (A), (B), (C) and optional (D), material of the present invention also can contain other materials, for example: softening agent (E), filler (F), adhesion promoter (G) and additive (H), these other materials (E) to (H) also can with at present can anhydrous storage and add in the water crosslinkable material used identical.
The example of softening agent (E) is: under the room temperature for liquid and with the end capped dimethyl polysiloxane of trimethyl silicane alcoxyl base (especially viscosity is 50 to 1000 pascal seconds in the least), and high boiling hydrocarbon, for example: whiteruss.
With 100 weight part organopolysiloxanes (A) is benchmark, preferred 0 to 300 weight part of the content of material internal plasticizer of the present invention (E), preferred especially 10 to 200 weight parts, especially 20 to 100 weight parts.
The example of filler (F) is a non-enhanced filler, be the filler of BET surface-area up to 50 meters squared per gram, for example: quartz, diatomite, Calucium Silicate powder, zirconium silicate, zeolite, metal oxide powder, for example: the oxide compound of aluminium, titanium, iron or zinc or its hopcalite, barium sulfate, lime carbonate, gypsum, silicon nitride, silicon carbide, boron nitride, glass powder and synthetic resin moulding compound, for example: the polyacrylonitrile powder; Enhancing property filler, promptly the BET surface-area is greater than the filler of 50 meters squared per gram, for example: silica, appositional pattern silica, the appositional pattern chalk of pyrolysis preparation, carbon black, for example: furnace black and acetylene black, and the big silicon-aluminium-mixed oxide of BET surface-area; The fibrous type filler, for example: asbestos and plastic optical fibre.Can impose the hydrophobization effect to these fillers, for example, by handling, or change into alkoxyl group by hydroxy ethers with organosilane or organo-siloxane or with stearic acid.If use filler (E), preferred hydrophilic pyrolysis-type silica and then through applying stearic chalk.
Be benchmark always with 100 weight part organopolysiloxanes (A), preferred 0 to 300 weight part of the filler of material of the present invention (F) content, preferred especially 1 to 200 weight part, especially 5 to 200 weight parts.
The example of used adhesion promoter (G) is in the material of the present invention: have silane and organopolysiloxane that functional group for example has glycidyl oxygen propyl group or methacryloyl oxygen propyl group, and tetraalkoxysilane.Yet,, can save the interpolation adhesion promoter if another component such as siloxanes (A) or linking agent (B) have these functional groups.
With 100 weight part organopolysiloxanes (A) is benchmark, preferred 0 to 50 weight part of the adhesion promoter of material of the present invention (G) content, preferred especially 1 to 20 weight part, especially 1 to 10 weight part.
The example of additive (H) is: pigment, dyestuff, spices, mycocide, antioxidant, influence the component of electrical property such as the component of electrical conductivity Carbon black, flame delayed-action activator component, photostabilizer and increase epidermis formation time, for example: silane with SiC-bond mercapto alkyl, produce the composition of hole, for example: azodicarboamide, thermo-stabilizer and thixotropic agent, for example: phosphoric acid ester, and organic solvent, for example: Alkylaromatics.
With 100 weight part organopolysiloxanes (A) is benchmark, preferred 0 to 100 weight part of the additive of material of the present invention (H) content, preferred especially 0 to 30 weight part, especially 0 to 10 weight part.
Preferred especially material of the present invention contains following component:
(A) diorganopolysiloxanecompositions of formula V, optional
(B) linking agent of formula (VI) and/or its partial hydrolysate,
(C) organo-tin compound reaches
(D) has formula (IV) compound of basic nitrogen.
Especially preferred material of the present invention is made up of following all components:
(A) polydiorganosiloxane of 100 weight part formula V,
(B) linking agent of 0.01 to 20 weight part formula (VI) and/or its partial hydrolysate,
(C) 0.05 to 3 weight part organo-tin compound,
(D) 0.01 to 4 weight part has formula (IV) compound of basic nitrogen,
(E) 0 to 300 weight part softening agent,
(F) 0 to 300 weight part filler,
(G) 0 to 50 weight part adhesion promoter reaches
(H) 0 to 100 weight part additive.
The individual components of material of the present invention can be respectively the mixture that a kind of this type of component also can at least two different types of these components.
When preparing material of the present invention, all components of each material can be mixed with each other according to the order of any expection.This mixing can be at room temperature and barometric point, promptly implement under about 900 to 1,100 hundred pascals.But in case of necessity, this hybrid working also can be under higher temperatures, for example implement in 35 ℃ to 135 ℃ temperature ranges.
The preparation of material of the present invention and storage thereof must be implemented under the substantially anhydrous situation, otherwise these materials can solidify ahead of time.
For making material of the present invention crosslinked to make elastomerics, airborne common water content is enough.In case of necessity, crosslinked action also can be implemented being higher than room temperature or being lower than under the room temperature, for example :-5 ℃ to 15 ℃ or 30 ℃ to 50 ℃.The crosslinked pressure of preferred enforcement is 100 to 1,100 hundred pascals, especially under barometric point.
The invention still further relates to the moulded product of making by crosslinked material of the present invention.
The advantage of crosslinkable materials of the present invention is: the preservation period thresold is long and cross-linked speed is high.
Surprised is by in conjunction with sulfur-containing group and phosphorus-containing groups, can significantly improve the storage life of crosslinkable materials and significantly increase its cross-linked speed.
Moreover, utilize the prepared material of the present invention of organo-tin compound (C) to have colourless and transparent advantage.
Allly can store and at room temperature meet the water crosslinkable generate the spendable occasion of elastomeric material under anhydrous situation, material of the present invention all can use.
Therefore material of the present invention extremely is fit to for example as the joint seal compound; comprise vertical joint and interior dimensions and be for example 10 to 40 millimeters similar spaces; for example: buildings, land vehicle, ships and aircraft; or as tackiness agent or jointing material; for example in door and window making or aquarium or glass cabinet, reach and for example make protective cover; comprise the surperficial needed of frequent contact fresh water or seawater, or skid-resistant coating, or in order to make elastomer molded body and to be used for motor or the insulation of electronic equipment.
Embodiment
In following all embodiment, all viscosity datas all are to measure under 25 ℃ of temperature.Unless otherwise indicated, the enforcement of following all embodiment all be under atmospheric pressure under (promptly about 1,000 hundred pascals) and the room temperature (promptly about 23 ℃) at room temperature need not to heat or cool off and combine reactant under the temperature that is produced and the situation of relative humidity about 50% under.Moreover, unless otherwise indicated outside, all umbers and per-cent all are based on weight.
Among following all embodiment the storage life of made RTV-1 alkoxyl group material (=compound) be by cutification time of these compounds, it generates sulfuration of elastic caoutchouc and the Shore A measurement of hardness that changes with the storage time.The solarization of these compounds quickens by storing under 100 ℃ of temperature.
Embodiment 1
The preparation of tin catalyst 1:
16 gram Witco 1298 Soft Acids and 6 gram phosphenylic acids are added in the 40 gram tin compounds, and this tin compound is to be reacted and made by 4 parts of tetraethoxysilanes and 2.2 parts of dibutyltin diacetates, and formed methyl alcohol is to remove in a vacuum.Gained be viscosity, transparent compound.
Under the situation of anhydrous existence, in having the planetary-type mixer of vacuum apparatus, what make 55.4 weight parts has-OSi (OCH 3) 2(CH 3) end group, viscosity be that the polydimethylsiloxane and 31.2 weight parts of 80000 milli pascal seconds have-OSi (CH 3) 3End group, viscosity are that polydimethylsiloxane, 4.0 weight part methyltrimethoxy silanes and the 1.5 weight part 3-aminopropyl trimethoxysilane of 100 milli pascal seconds are mixed.Sneak into 8.0 weight parts afterwards, the BET surface-area is the pyrolysis-type silica (being buied with trade name " WACKER HDK V15 " by Wacker-Chemie GmbH) of 150 meters squared per gram, adds the above-mentioned tin catalyst of 0.15 weight part 1 at last.In vacuum in addition homogenizing after, made compound like this is packed in the water-proof container, and in table 1, makes it crosslinked after the described storage time.For reaching this purpose, the thin layer of made compound like this with 2 mm thick is coated on the polyethylene film, and it is statically placed in the environment of 23 ℃ of temperature and relative humidity 50%.If this material is completely solidified after 24 hours, then this solidification is chosen as good.
In addition, measure cutification time and measure the Shore A hardness of 6 mm thick elastomeric plates after solidifying 7 days under the situation of 23 ℃ of temperature and relative humidity 50%.
The result of storage and curing performance is as shown in table 1.
Embodiment 2
The preparation of tin catalyst 2
In toluene,, and remove with the water that the azeotropic mode will react generation with oxidation di-n-butyl tin and 1 molar equivalent the phosphenylic acid of Witco 1298 Soft Acid monohydrate and 1 molar equivalent is refluxed.Residue is dissolved in a small amount of methyltrimethoxy silane, makes highly viscous liquid.
The program of embodiment 1 is come again, but different be to use 0.15 weight part tin catalyst 2 to replace 0.15 weight part tin catalyst 1.
The result of storage and curing performance is as shown in table 1.
Comparative example 1
The relatively preparation of catalyst A
16 gram Witco 1298 Soft Acids are added in the 40 gram tin compounds, and this tin compound is reacted by 4 parts of tetraethoxysilanes and 2.2 parts of dibutyltin diacetates and makes, and formed methyl alcohol is removed in a vacuum.Obtain viscosity, transparent compound.
The program of embodiment 1 is come again, but different is: use 0.2 weight part ratio than catalyst A to replace 0.15 weight part tin catalyst 1.
The result of storage and curing performance is as shown in table 1.
Comparative example 2
The relatively preparation of catalyst B
8 gram Witco 1298 Soft Acids are added into 40 grams, four n-octyl dimethoxy distannoxanes, and formed methyl alcohol is removed in a vacuum.Obtain viscosity, transparent compound.
The program of embodiment 1 is come again, but different is: use 0.2 weight part ratio than catalyst B to replace 0.15 weight part tin catalyst 1.
The result of storage and curing performance is as shown in table 1.
Embodiment 3
Under the situation of anhydrous existence,, 55.4 weight parts are had-OSi (OCH in in the planetary-type mixer of vacuum apparatus 3) 2(CH 3) end group, viscosity be that the polydimethylsiloxane and 31.2 weight parts of 80000 milli pascal seconds have-OSi (CH 3) 3End group, viscosity are that tin compound (this tin compound is to be made with the reaction of 2.2 parts of dibutyltin diacetates by 4 parts of tetraethoxysilanes), 0.05 weight part phosphenylic acid (it is interior to be dissolved in methyltrimethoxy silane) and the 0.1 weight part Witco 1298 Soft Acid of polydimethylsiloxane, 4.0 weight part methyltrimethoxy silanes and 0.2 weight part of 100 milli pascal seconds mixes and stirred 10 minutes.Sneak into the pyrolysis-type silica that 8.0 weight part BET surface-area are 1 50 meters squared per gram (buying for " WACKER HDK V15 " with trade(brand)name) afterwards, add 1.5 weight part 3-aminopropyl trimethoxysilane at last by Wacker-ChemieGmbH.In vacuum after the homogenizing, as described in example 1 above, made compound like this is packed in the water-proof container, and in table 1, make it crosslinked after the described storage time.
The result of storage and curing performance is as shown in table 1.
Comparative example 3
Under the situation of anhydrous existence,, 55.4 weight parts are had-OSi (OCH in in the planetary-type mixer of vacuum apparatus 3) 2(CH 3) end group, viscosity be that the polydimethylsiloxane and 31.2 weight parts of 80000 milli pascal seconds have-OSi (CH 3) 3End group, viscosity are that the tin compound (this tin compound is to be reacted with 2.2 parts of dibutyltin diacetates by 4 parts of tetraethoxysilanes to make) of polydimethylsiloxane, 4.0 weight part methyltrimethoxy silanes and 0.2 weight part of 100 milli pascal seconds and 0.3 weight part phosphenylic acid (saturated solution in methyltrimethoxy silane) mix and stirred 10 minutes.Sneak into the pyrolysis-type silica that 8.0 weight part BET surface-area are 150 meters squared per gram afterwards and (be " WACKER HDK with trade(brand)name by Wacker-Chemie GmbH V15 " buy), 1.5 weight part 3-aminopropyl trimethoxysilane added at last.In vacuum after the homogenizing, as described in example 1 above, made compound like this is packed in the water-proof container, and in table 1, make it crosslinked after the described storage time.
The result of storage and curing performance is as shown in table 1.
Table 1:
Store at 100 ℃ that after x days solidification is good Cutification after 0 day/100 ℃ time/Shore A hardness Cutification after 1 day/100 ℃ time/Shore A hardness Cutification after 2 days/100 ℃ time/Shore A hardness Cutification after 3 days/100 ℃ time/Shore A hardness
Embodiment 1 ?7 ?15/21 ?18/19 ?18/18 ?19/18
Embodiment 2 ?6 ?17/21 ?24/19 ?18/17 ?20/17
Comparative example 1 ?3 ?10/21 ?12/9 ?15/2 No solidification
Comparative example 2 ?3 ?15/15 ?18/15 ?28/12 ?30/8
Embodiment 5 ?8 ?15/21 ?18/19 ?18/17 ?19/16
Comparative example 3 ?2 ?25/16 ?23/10 ?80/4 No solidification

Claims (10)

1. crosslinkable materials based on silicoorganic compound with at least two hydrolyzable bases, wherein contain at least a organo-tin compound (C) as catalyzer, this organo-tin compound (C) can by have C-P (=O) (OH) unitary phosphorus compound (i) with have-SO 3The sulphur compound of H base (ii) reaches and contains the unitary tin compound of following formula and (iii) react and make
R a(XR′) bSnX (4-a-b)/2???????????????????(III),
In the formula,
R is identical or different, and be monovalent, optional be substituted can be by Sauerstoffatom alkyl at interval,
X is identical or different, and be-O-or-S-,
R ' is identical or different, and be hydrogen atom or monovalent, optional be substituted can be by Sauerstoffatom alkyl or the optional silyl that is substituted at interval,
A be 0,1,2 or 3 and
B is 0,1,2 or 3,
Condition be a+b and be less than or equal to 4.
2. material as claimed in claim 1, it contains and has alkaline nitrogen compound (D).
3. material as claimed in claim 2, wherein said have alkaline nitrogen compound (D) and be selected from following group: amine, nitrogen heterocyclic ring and amino-functional silicoorganic compound.
4. as the material of claim 2 or 3, wherein said to have alkaline nitrogen compound (D) be the amino-functional silicoorganic compound.
5. as the material of one of claim 2-4, wherein said have silicoorganic compound and a partial hydrolysate thereof that alkaline nitrogen compound (D) is a following formula:
(R 9O) 4-gSiR 10 g?????????????(IV),
Wherein
R 9Be identical or different, and have one of meaning of above-mentioned R ',
R 10Be identical or different, and be monovalent, the optional alkyl that is substituted with basic nitrogen, and
G is 1,2,3 or 4.
6. as the material of one of claim 1-5, wherein said crosslinkable materials contains following component:
(A) have at least two organopolysiloxanes that are selected from the hydrolyzable base of acetoxyl group, oximate base and organic oxygen base, optional
(B) have at least three linking agent and/or its partial hydrolysates that are selected from the hydrolyzable base of acetoxyl group, oximate base and organic oxygen base,
(C) can (ii) reach tin compound by phosphorus compound (i), sulphur compound and (iii) react the organo-tin compound that makes, and optional
(D) has alkaline nitrogen compound (D).
7, as the material of one of claim 1-6, wherein said crosslinkable materials contains following component:
(A) diorganopolysiloxanecompositions of formula V, optional
(B) linking agent of formula (VI) and/or its partial hydrolysate,
(C) organo-tin compound and
(D) has the compound of the formula (IV) of basic nitrogen.
8. as the material of one of claim 1-7, wherein said crosslinkable materials is composed of the following components:
(A) polydiorganosiloxane of 100 weight part formula V,
(B) linking agent of 0.01 to 20 weight part formula (VI) and/or its partial hydrolysate,
(C) 0.05 to 3 weight part organo-tin compound,
(D) 0.01 to 4 weight part has the compound of the formula (IV) of basic nitrogen,
(E) 0 to 300 weight part softening agent,
(F) 0 to 300 weight part filler,
(G) 0 to 50 weight part adhesion promoter and
(H) 0 to 100 weight part additive.
9. organo-tin compound, its can by have C-P (=O) (OH) unitary phosphorus compound (i) with have-SO 3The sulphur compound of H base (ii) reaches and contains the unitary tin compound of following formula and (iii) react and make:
R a(XR′) bSnX (4-a-b)/2????????????(III),
Wherein R, X, R ', a and b have above-mentioned meaning, condition be a+b and be less than or equal to 4.
10. moulded product that makes by the material of one of crosslinked claim 1-8.
CNB02820509XA 2001-10-18 2002-10-02 Cross-linkable materials based on organosilicon compounds Expired - Fee Related CN1253509C (en)

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